This Minireview presents recent important homogenous aerobic oxidative reactions which are assisted by electron transfer mediators (ETMs). Compared with direct oxidation by molecular oxygen (O2), the use of a coupled catalyst system with ETMs leads to a lower overall energy barrier via stepwise electron transfer. This cooperative catalytic process significantly facilitates the transport of electrons from the reduced form of the substrate‐selective redox catalyst (SSRCred) to O2, thereby increasing the efficiency of the aerobic oxidation. In this Minireview, we have summarized the advances accomplished in recent years in transition‐metal‐catalyzed as well as metal‐free aerobic oxidations of organic molecules in the presence of ETMs. In addition, the recent progress of photochemical and electrochemical oxidative functionalization using ETMs and O2 as the terminal oxidant is also highlighted. Furthermore, the mechanisms of these transformations are showcased.
We report the first FeII‐catalyzed biomimetic aerobic oxidation of alcohols. The principle of this oxidation, which involves several electron‐transfer steps, is reminiscent of biological oxidation in the respiratory chain. The electron transfer from the alcohol to molecular oxygen occurs with the aid of three coupled catalytic redox systems, leading to a low‐energy pathway. An iron transfer‐hydrogenation complex was utilized as a substrate‐selective dehydrogenation catalyst, along with an electron‐rich quinone and an oxygen‐activating Co(salen)‐type complex as electron‐transfer mediators. Various primary and secondary alcohols were oxidized in air to the corresponding aldehydes or ketones with this method in good to excellent yields.
Herein, we report on a metalloenzymatic dynamic kinetic resolution of sec-alcohols employing an iron-based racemization catalyst together with a lipase. The iron catalyst was evaluated in racemization and then used in dynamic kinetic resolution of a number of sec-alcohols to give enantiomerically pure products in good to high yields. The iron catalyst is air and moisture stable and is readily accessible.
Herein, we report a highly efficient
iron-catalyzed intramolecular
nucleophilic cyclization of α-allenols to furnish substituted
2,3-dihydrofurans under mild reaction conditions. A highly diastereoselective
variant of the reaction was developed as well, giving diastereomeric
ratios of up to 98:2. The combination of the iron-catalyzed cycloisomerization
with enzymatic resolution afforded the 2,3-dihydrofuran in high ee.
A detailed DFT study provides insight into the reaction mechanism
and gives a rationalization for the high chemo- and diastereoselectivity.
Transition metal catalysis in modern organic synthesis has largely focused on noble transition metals like palladium, platinum and ruthenium. The toxicity and low abundance of these metals, however, has led to a rising focus on the development of the more sustainable base metals like iron, copper and nickel for use in catalysis. Iron is a particularly good candidate for this purpose due to its abundance, wide redox potential range, and the ease with which its properties can be tuned through the exploitation of its multiple oxidation states, electron spin states and redox potential. This is a fact made clear by all life on Earth, where iron is used as a cornerstone in the chemistry of living processes. In this mini review, we report on the general advancements in the field of iron catalysis in organic chemistry covering addition reactions, C-H activation, cross-coupling reactions, cycloadditions, isomerization and redox reactions.
A highly
selective palladium-catalyzed hydroborylative carbocyclization of
bisallenes to afford seven-membered rings has been established. This
ring-closing coupling reaction showed good functional group compatibility
with high chemo- and regioselectivity, as seven-membered ring 3 was the only product obtained. The extensive use of different
linkers, including nitrogen, oxygen, malononitrile, and malonate,
showed a broad substrate scope for this approach. A one-pot cascade
reaction was realized by trapping the primary allylboron compound
with an aldehyde, affording a diastereomerically pure alcohol and
a quaternary carbon center by formation of a new C–C bond.
A comprehensive mechanistic DFT investigation is also presented. The
calculations suggest that the reaction proceeds via a concerted hydropalladation
pathway from a Pd(0)-olefin complex rather than via a pathway involving
a defined palladium hydride species. The reaction was significantly
accelerated by the coordination of the pendant olefin, as well as
the introduction of suitable substituents in the bridge, due to the
Thorpe–Ingold effect.
Herein,
we report the synthesis of 2,3-dihydropyrroles via an iron-catalyzed intramolecular nucleophilic
cyclization of α-allenic sulfonamides. A highly diastereoselective
variant of the reaction was also developed with the use of 1,2-disubstituted
allenamides, which afforded 2,3-dihydropyrroles with diastereomeric
ratios of >98:2. Insight into the mechanism was gained through
a detailed
DFT study, which elucidates the reaction mechanism and rationalizes
the high chemoselectivity and diastereoselectivity.
The activation process of a known Ru‐catalyst, dicarbonyl(pentaphenylcyclopentadienyl)ruthenium chloride, has been studied in detail using time resolved in situ X‐ray absorption spectroscopy. The data provide bond lengths of the species involved in the process as well as information about bond formation and bond breaking. On addition of potassium tert‐butoxide, the catalyst is activated and an alkoxide complex is formed. The catalyst activation proceeds via a key acyl intermediate, which gives rise to a complete structural change in the coordination environment around the Ru atom. The rate of activation for the different catalysts was found to be highly dependent on the electronic properties of the cyclopentadienyl ligand. During catalytic racemization of 1‐phenylethanol a fast‐dynamic equilibrium was observed.
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